/* Handle #pragma, system V.4 style. Supports #pragma weak and #pragma pack. Copyright (C) 1992, 1997, 1998, 1999, 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008 Free Software Foundation, Inc. This file is part of GCC. GCC is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3, or (at your option) any later version. GCC is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with GCC; see the file COPYING3. If not see . */ #include "config.h" #include "system.h" #include "coretypes.h" #include "tm.h" #include "rtl.h" #include "tree.h" #include "function.h" #include "cpplib.h" #include "c-pragma.h" #include "flags.h" #include "toplev.h" #include "ggc.h" #include "c-common.h" #include "output.h" #include "tm_p.h" #include "vec.h" #include "target.h" #include "diagnostic.h" #include "opts.h" #define GCC_BAD(gmsgid) \ do { warning (OPT_Wpragmas, gmsgid); return; } while (0) #define GCC_BAD2(gmsgid, arg) \ do { warning (OPT_Wpragmas, gmsgid, arg); return; } while (0) typedef struct align_stack GTY(()) { int alignment; tree id; struct align_stack * prev; } align_stack; static GTY(()) struct align_stack * alignment_stack; #ifdef HANDLE_PRAGMA_PACK static void handle_pragma_pack (cpp_reader *); #ifdef HANDLE_PRAGMA_PACK_PUSH_POP /* If we have a "global" #pragma pack() in effect when the first #pragma pack(push,) is encountered, this stores the value of maximum_field_alignment in effect. When the final pop_alignment() happens, we restore the value to this, not to a value of 0 for maximum_field_alignment. Value is in bits. */ static int default_alignment; #define SET_GLOBAL_ALIGNMENT(ALIGN) (maximum_field_alignment = *(alignment_stack == NULL \ ? &default_alignment \ : &alignment_stack->alignment) = (ALIGN)) static void push_alignment (int, tree); static void pop_alignment (tree); /* Push an alignment value onto the stack. */ static void push_alignment (int alignment, tree id) { align_stack * entry; entry = GGC_NEW (align_stack); entry->alignment = alignment; entry->id = id; entry->prev = alignment_stack; /* The current value of maximum_field_alignment is not necessarily 0 since there may be a #pragma pack() in effect; remember it so that we can restore it after the final #pragma pop(). */ if (alignment_stack == NULL) default_alignment = maximum_field_alignment; alignment_stack = entry; maximum_field_alignment = alignment; } /* Undo a push of an alignment onto the stack. */ static void pop_alignment (tree id) { align_stack * entry; if (alignment_stack == NULL) GCC_BAD ("#pragma pack (pop) encountered without matching #pragma pack (push)"); /* If we got an identifier, strip away everything above the target entry so that the next step will restore the state just below it. */ if (id) { for (entry = alignment_stack; entry; entry = entry->prev) if (entry->id == id) { alignment_stack = entry; break; } if (entry == NULL) warning (OPT_Wpragmas, "\ #pragma pack(pop, %s) encountered without matching #pragma pack(push, %s)" , IDENTIFIER_POINTER (id), IDENTIFIER_POINTER (id)); } entry = alignment_stack->prev; maximum_field_alignment = entry ? entry->alignment : default_alignment; alignment_stack = entry; } #else /* not HANDLE_PRAGMA_PACK_PUSH_POP */ #define SET_GLOBAL_ALIGNMENT(ALIGN) (maximum_field_alignment = (ALIGN)) #define push_alignment(ID, N) \ GCC_BAD ("#pragma pack(push[, id], ) is not supported on this target") #define pop_alignment(ID) \ GCC_BAD ("#pragma pack(pop[, id], ) is not supported on this target") #endif /* HANDLE_PRAGMA_PACK_PUSH_POP */ /* #pragma pack () #pragma pack (N) #pragma pack (push) #pragma pack (push, N) #pragma pack (push, ID) #pragma pack (push, ID, N) #pragma pack (pop) #pragma pack (pop, ID) */ static void handle_pragma_pack (cpp_reader * ARG_UNUSED (dummy)) { tree x, id = 0; int align = -1; enum cpp_ttype token; enum { set, push, pop } action; if (pragma_lex (&x) != CPP_OPEN_PAREN) GCC_BAD ("missing %<(%> after %<#pragma pack%> - ignored"); token = pragma_lex (&x); if (token == CPP_CLOSE_PAREN) { action = set; align = initial_max_fld_align; } else if (token == CPP_NUMBER) { if (TREE_CODE (x) != INTEGER_CST) GCC_BAD ("invalid constant in %<#pragma pack%> - ignored"); align = TREE_INT_CST_LOW (x); action = set; if (pragma_lex (&x) != CPP_CLOSE_PAREN) GCC_BAD ("malformed %<#pragma pack%> - ignored"); } else if (token == CPP_NAME) { #define GCC_BAD_ACTION do { if (action != pop) \ GCC_BAD ("malformed %<#pragma pack(push[, id][, ])%> - ignored"); \ else \ GCC_BAD ("malformed %<#pragma pack(pop[, id])%> - ignored"); \ } while (0) const char *op = IDENTIFIER_POINTER (x); if (!strcmp (op, "push")) action = push; else if (!strcmp (op, "pop")) action = pop; else GCC_BAD2 ("unknown action %qs for %<#pragma pack%> - ignored", op); while ((token = pragma_lex (&x)) == CPP_COMMA) { token = pragma_lex (&x); if (token == CPP_NAME && id == 0) { id = x; } else if (token == CPP_NUMBER && action == push && align == -1) { if (TREE_CODE (x) != INTEGER_CST) GCC_BAD ("invalid constant in %<#pragma pack%> - ignored"); align = TREE_INT_CST_LOW (x); if (align == -1) action = set; } else GCC_BAD_ACTION; } if (token != CPP_CLOSE_PAREN) GCC_BAD_ACTION; #undef GCC_BAD_ACTION } else GCC_BAD ("malformed %<#pragma pack%> - ignored"); if (pragma_lex (&x) != CPP_EOF) warning (OPT_Wpragmas, "junk at end of %<#pragma pack%>"); if (flag_pack_struct) GCC_BAD ("#pragma pack has no effect with -fpack-struct - ignored"); if (action != pop) switch (align) { case 0: case 1: case 2: case 4: case 8: case 16: align *= BITS_PER_UNIT; break; case -1: if (action == push) { align = maximum_field_alignment; break; } default: GCC_BAD2 ("alignment must be a small power of two, not %d", align); } switch (action) { case set: SET_GLOBAL_ALIGNMENT (align); break; case push: push_alignment (align, id); break; case pop: pop_alignment (id); break; } } #endif /* HANDLE_PRAGMA_PACK */ struct def_pragma_macro_value GTY(()) { struct def_pragma_macro_value *prev; cpp_macro *value; }; struct def_pragma_macro GTY(()) { hashval_t hash; const char *name; struct def_pragma_macro_value value; }; static GTY((param_is (struct def_pragma_macro))) htab_t pushed_macro_table; #ifdef HANDLE_PRAGMA_PUSH_POP_MACRO /* Hash table control functions for pushed_macro_table. */ static hashval_t dpm_hash (const void *p) { return ((const struct def_pragma_macro *)p)->hash; } static int dpm_eq (const void *pa, const void *pb) { const struct def_pragma_macro *const a = (const struct def_pragma_macro *) pa, *const b = (const struct def_pragma_macro *) pb; return a->hash == b->hash && strcmp (a->name, b->name) == 0; } /* #pragma push_macro("MACRO_NAME") #pragma pop_macro("MACRO_NAME") */ static void handle_pragma_push_macro (cpp_reader *reader) { tree x, id = 0; enum cpp_ttype token; struct def_pragma_macro dummy, *c; const char *macroname; void **slot; if (pragma_lex (&x) != CPP_OPEN_PAREN) GCC_BAD ("missing %<(%> after %<#pragma push_macro%> - ignored"); token = pragma_lex (&id); /* Silently ignore */ if (token == CPP_CLOSE_PAREN) return; if (token != CPP_STRING) GCC_BAD ("invalid constant in %<#pragma push_macro%> - ignored"); if (pragma_lex (&x) != CPP_CLOSE_PAREN) GCC_BAD ("missing %<)%> after %<#pragma push_macro%> - ignored"); if (pragma_lex (&x) != CPP_EOF) warning (OPT_Wpragmas, "junk at end of %<#pragma push_macro%>"); /* Check for empty string, and silently ignore. */ if (TREE_STRING_LENGTH (id) < 1) return; macroname = TREE_STRING_POINTER (id); if (pushed_macro_table == NULL) pushed_macro_table = htab_create_ggc (15, dpm_hash, dpm_eq, 0); dummy.hash = htab_hash_string (macroname); dummy.name = macroname; slot = htab_find_slot_with_hash (pushed_macro_table, &dummy, dummy.hash, INSERT); c = (struct def_pragma_macro *) *slot; if (c == NULL) { *slot = c = GGC_NEW (struct def_pragma_macro); c->hash = dummy.hash; c->name = ggc_alloc_string (macroname, TREE_STRING_LENGTH (id) - 1); c->value.prev = NULL; } else { struct def_pragma_macro_value *v; v = GGC_NEW (struct def_pragma_macro_value); *v = c->value; c->value.prev = v; } c->value.value = cpp_push_definition (reader, macroname); } static void handle_pragma_pop_macro (cpp_reader *reader) { tree x, id = 0; enum cpp_ttype token; struct def_pragma_macro dummy, *c; const char *macroname; void **slot = NULL; if (pragma_lex (&x) != CPP_OPEN_PAREN) GCC_BAD ("missing %<(%> after %<#pragma pop_macro%> - ignored"); token = pragma_lex (&id); /* Silently ignore */ if (token == CPP_CLOSE_PAREN) return; if (token != CPP_STRING) GCC_BAD ("invalid constant in %<#pragma pop_macro%> - ignored"); if (pragma_lex (&x) != CPP_CLOSE_PAREN) GCC_BAD ("missing %<)%> after %<#pragma pop_macro%> - ignored"); if (pragma_lex (&x) != CPP_EOF) warning (OPT_Wpragmas, "junk at end of %<#pragma pop_macro%>"); /* Check for empty string, and silently ignore. */ if (TREE_STRING_LENGTH (id) < 1) return; macroname = TREE_STRING_POINTER (id); dummy.hash = htab_hash_string (macroname); dummy.name = macroname; if (pushed_macro_table) slot = htab_find_slot_with_hash (pushed_macro_table, &dummy, dummy.hash, NO_INSERT); if (slot == NULL) return; c = (struct def_pragma_macro *) *slot; cpp_pop_definition (reader, c->name, c->value.value); if (c->value.prev) c->value = *c->value.prev; else htab_clear_slot (pushed_macro_table, slot); } #endif /* HANDLE_PRAGMA_PUSH_POP_MACRO */ static GTY(()) tree pending_weaks; #ifdef HANDLE_PRAGMA_WEAK static void apply_pragma_weak (tree, tree); static void handle_pragma_weak (cpp_reader *); static void apply_pragma_weak (tree decl, tree value) { if (value) { value = build_string (IDENTIFIER_LENGTH (value), IDENTIFIER_POINTER (value)); decl_attributes (&decl, build_tree_list (get_identifier ("alias"), build_tree_list (NULL, value)), 0); } if (SUPPORTS_WEAK && DECL_EXTERNAL (decl) && TREE_USED (decl) && !DECL_WEAK (decl) /* Don't complain about a redundant #pragma. */ && TREE_SYMBOL_REFERENCED (DECL_ASSEMBLER_NAME (decl))) warning (OPT_Wpragmas, "applying #pragma weak %q+D after first use " "results in unspecified behavior", decl); declare_weak (decl); } void maybe_apply_pragma_weak (tree decl) { tree *p, t, id; /* Avoid asking for DECL_ASSEMBLER_NAME when it's not needed. */ /* No weak symbols pending, take the short-cut. */ if (!pending_weaks) return; /* If it's not visible outside this file, it doesn't matter whether it's weak. */ if (!DECL_EXTERNAL (decl) && !TREE_PUBLIC (decl)) return; /* If it's not a function or a variable, it can't be weak. FIXME: what kinds of things are visible outside this file but aren't functions or variables? Should this be an assert instead? */ if (TREE_CODE (decl) != FUNCTION_DECL && TREE_CODE (decl) != VAR_DECL) return; id = DECL_ASSEMBLER_NAME (decl); for (p = &pending_weaks; (t = *p) ; p = &TREE_CHAIN (t)) if (id == TREE_PURPOSE (t)) { apply_pragma_weak (decl, TREE_VALUE (t)); *p = TREE_CHAIN (t); break; } } /* Process all "#pragma weak A = B" directives where we have not seen a decl for A. */ void maybe_apply_pending_pragma_weaks (void) { tree *p, t, alias_id, id, decl, *next; for (p = &pending_weaks; (t = *p) ; p = next) { next = &TREE_CHAIN (t); alias_id = TREE_PURPOSE (t); id = TREE_VALUE (t); if (TREE_VALUE (t) == NULL) continue; decl = build_decl (FUNCTION_DECL, alias_id, default_function_type); DECL_ARTIFICIAL (decl) = 1; TREE_PUBLIC (decl) = 1; DECL_EXTERNAL (decl) = 1; DECL_WEAK (decl) = 1; assemble_alias (decl, id); } } /* #pragma weak name [= value] */ static void handle_pragma_weak (cpp_reader * ARG_UNUSED (dummy)) { tree name, value, x, decl; enum cpp_ttype t; value = 0; if (pragma_lex (&name) != CPP_NAME) GCC_BAD ("malformed #pragma weak, ignored"); t = pragma_lex (&x); if (t == CPP_EQ) { if (pragma_lex (&value) != CPP_NAME) GCC_BAD ("malformed #pragma weak, ignored"); t = pragma_lex (&x); } if (t != CPP_EOF) warning (OPT_Wpragmas, "junk at end of %<#pragma weak%>"); decl = identifier_global_value (name); if (decl && DECL_P (decl)) { apply_pragma_weak (decl, value); if (value) assemble_alias (decl, value); } else pending_weaks = tree_cons (name, value, pending_weaks); } #else void maybe_apply_pragma_weak (tree ARG_UNUSED (decl)) { } void maybe_apply_pending_pragma_weaks (void) { } #endif /* HANDLE_PRAGMA_WEAK */ /* GCC supports two #pragma directives for renaming the external symbol associated with a declaration (DECL_ASSEMBLER_NAME), for compatibility with the Solaris and Tru64 system headers. GCC also has its own notation for this, __asm__("name") annotations. Corner cases of these features and their interaction: 1) Both pragmas silently apply only to declarations with external linkage (that is, TREE_PUBLIC || DECL_EXTERNAL). Asm labels do not have this restriction. 2) In C++, both #pragmas silently apply only to extern "C" declarations. Asm labels do not have this restriction. 3) If any of the three ways of changing DECL_ASSEMBLER_NAME is applied to a decl whose DECL_ASSEMBLER_NAME is already set, and the new name is different, a warning issues and the name does not change. 4) The "source name" for #pragma redefine_extname is the DECL_NAME, *not* the DECL_ASSEMBLER_NAME. 5) If #pragma extern_prefix is in effect and a declaration occurs with an __asm__ name, the #pragma extern_prefix is silently ignored for that declaration. 6) If #pragma extern_prefix and #pragma redefine_extname apply to the same declaration, whichever triggered first wins, and a warning is issued. (We would like to have #pragma redefine_extname always win, but it can appear either before or after the declaration, and if it appears afterward, we have no way of knowing whether a modified DECL_ASSEMBLER_NAME is due to #pragma extern_prefix.) */ static GTY(()) tree pending_redefine_extname; static void handle_pragma_redefine_extname (cpp_reader *); /* #pragma redefine_extname oldname newname */ static void handle_pragma_redefine_extname (cpp_reader * ARG_UNUSED (dummy)) { tree oldname, newname, decl, x; enum cpp_ttype t; if (pragma_lex (&oldname) != CPP_NAME) GCC_BAD ("malformed #pragma redefine_extname, ignored"); if (pragma_lex (&newname) != CPP_NAME) GCC_BAD ("malformed #pragma redefine_extname, ignored"); t = pragma_lex (&x); if (t != CPP_EOF) warning (OPT_Wpragmas, "junk at end of %<#pragma redefine_extname%>"); if (!flag_mudflap && !targetm.handle_pragma_redefine_extname) { if (warn_unknown_pragmas > in_system_header) warning (OPT_Wunknown_pragmas, "#pragma redefine_extname not supported on this target"); return; } decl = identifier_global_value (oldname); if (decl && (TREE_PUBLIC (decl) || DECL_EXTERNAL (decl)) && (TREE_CODE (decl) == FUNCTION_DECL || TREE_CODE (decl) == VAR_DECL) && has_c_linkage (decl)) { if (DECL_ASSEMBLER_NAME_SET_P (decl)) { const char *name = IDENTIFIER_POINTER (DECL_ASSEMBLER_NAME (decl)); name = targetm.strip_name_encoding (name); if (strcmp (name, IDENTIFIER_POINTER (newname))) warning (OPT_Wpragmas, "#pragma redefine_extname ignored due to " "conflict with previous rename"); } else change_decl_assembler_name (decl, newname); } else /* We have to add this to the rename list even if there's already a global value that doesn't meet the above criteria, because in C++ "struct foo {...};" puts "foo" in the current namespace but does *not* conflict with a subsequent declaration of a function or variable foo. See g++.dg/other/pragma-re-2.C. */ add_to_renaming_pragma_list (oldname, newname); } /* This is called from here and from ia64.c. */ void add_to_renaming_pragma_list (tree oldname, tree newname) { tree previous = purpose_member (oldname, pending_redefine_extname); if (previous) { if (TREE_VALUE (previous) != newname) warning (OPT_Wpragmas, "#pragma redefine_extname ignored due to " "conflict with previous #pragma redefine_extname"); return; } pending_redefine_extname = tree_cons (oldname, newname, pending_redefine_extname); } static GTY(()) tree pragma_extern_prefix; /* #pragma extern_prefix "prefix" */ static void handle_pragma_extern_prefix (cpp_reader * ARG_UNUSED (dummy)) { tree prefix, x; enum cpp_ttype t; if (pragma_lex (&prefix) != CPP_STRING) GCC_BAD ("malformed #pragma extern_prefix, ignored"); t = pragma_lex (&x); if (t != CPP_EOF) warning (OPT_Wpragmas, "junk at end of %<#pragma extern_prefix%>"); if (targetm.handle_pragma_extern_prefix) /* Note that the length includes the null terminator. */ pragma_extern_prefix = (TREE_STRING_LENGTH (prefix) > 1 ? prefix : NULL); else if (warn_unknown_pragmas > in_system_header) warning (OPT_Wunknown_pragmas, "#pragma extern_prefix not supported on this target"); } /* Hook from the front ends to apply the results of one of the preceding pragmas that rename variables. */ tree maybe_apply_renaming_pragma (tree decl, tree asmname) { tree *p, t; /* The renaming pragmas are only applied to declarations with external linkage. */ if ((TREE_CODE (decl) != FUNCTION_DECL && TREE_CODE (decl) != VAR_DECL) || (!TREE_PUBLIC (decl) && !DECL_EXTERNAL (decl)) || !has_c_linkage (decl)) return asmname; /* If the DECL_ASSEMBLER_NAME is already set, it does not change, but we may warn about a rename that conflicts. */ if (DECL_ASSEMBLER_NAME_SET_P (decl)) { const char *oldname = IDENTIFIER_POINTER (DECL_ASSEMBLER_NAME (decl)); oldname = targetm.strip_name_encoding (oldname); if (asmname && strcmp (TREE_STRING_POINTER (asmname), oldname)) warning (OPT_Wpragmas, "asm declaration ignored due to " "conflict with previous rename"); /* Take any pending redefine_extname off the list. */ for (p = &pending_redefine_extname; (t = *p); p = &TREE_CHAIN (t)) if (DECL_NAME (decl) == TREE_PURPOSE (t)) { /* Only warn if there is a conflict. */ if (strcmp (IDENTIFIER_POINTER (TREE_VALUE (t)), oldname)) warning (OPT_Wpragmas, "#pragma redefine_extname ignored due to " "conflict with previous rename"); *p = TREE_CHAIN (t); break; } return 0; } /* Find out if we have a pending #pragma redefine_extname. */ for (p = &pending_redefine_extname; (t = *p); p = &TREE_CHAIN (t)) if (DECL_NAME (decl) == TREE_PURPOSE (t)) { tree newname = TREE_VALUE (t); *p = TREE_CHAIN (t); /* If we already have an asmname, #pragma redefine_extname is ignored (with a warning if it conflicts). */ if (asmname) { if (strcmp (TREE_STRING_POINTER (asmname), IDENTIFIER_POINTER (newname)) != 0) warning (OPT_Wpragmas, "#pragma redefine_extname ignored due to " "conflict with __asm__ declaration"); return asmname; } /* Otherwise we use what we've got; #pragma extern_prefix is silently ignored. */ return build_string (IDENTIFIER_LENGTH (newname), IDENTIFIER_POINTER (newname)); } /* If we've got an asmname, #pragma extern_prefix is silently ignored. */ if (asmname) return asmname; /* If #pragma extern_prefix is in effect, apply it. */ if (pragma_extern_prefix) { const char *prefix = TREE_STRING_POINTER (pragma_extern_prefix); size_t plen = TREE_STRING_LENGTH (pragma_extern_prefix) - 1; const char *id = IDENTIFIER_POINTER (DECL_NAME (decl)); size_t ilen = IDENTIFIER_LENGTH (DECL_NAME (decl)); char *newname = (char *) alloca (plen + ilen + 1); memcpy (newname, prefix, plen); memcpy (newname + plen, id, ilen + 1); return build_string (plen + ilen, newname); } /* Nada. */ return 0; } #ifdef HANDLE_PRAGMA_VISIBILITY static void handle_pragma_visibility (cpp_reader *); typedef enum symbol_visibility visibility; DEF_VEC_I (visibility); DEF_VEC_ALLOC_I (visibility, heap); static VEC (visibility, heap) *visstack; /* Push the visibility indicated by STR onto the top of the #pragma visibility stack. */ void push_visibility (const char *str) { VEC_safe_push (visibility, heap, visstack, default_visibility); if (!strcmp (str, "default")) default_visibility = VISIBILITY_DEFAULT; else if (!strcmp (str, "internal")) default_visibility = VISIBILITY_INTERNAL; else if (!strcmp (str, "hidden")) default_visibility = VISIBILITY_HIDDEN; else if (!strcmp (str, "protected")) default_visibility = VISIBILITY_PROTECTED; else GCC_BAD ("#pragma GCC visibility push() must specify default, internal, hidden or protected"); visibility_options.inpragma = 1; } /* Pop a level of the #pragma visibility stack. */ void pop_visibility (void) { default_visibility = VEC_pop (visibility, visstack); visibility_options.inpragma = VEC_length (visibility, visstack) != 0; } /* Sets the default visibility for symbols to something other than that specified on the command line. */ static void handle_pragma_visibility (cpp_reader *dummy ATTRIBUTE_UNUSED) { /* Form is #pragma GCC visibility push(hidden)|pop */ tree x; enum cpp_ttype token; enum { bad, push, pop } action = bad; token = pragma_lex (&x); if (token == CPP_NAME) { const char *op = IDENTIFIER_POINTER (x); if (!strcmp (op, "push")) action = push; else if (!strcmp (op, "pop")) action = pop; } if (bad == action) GCC_BAD ("#pragma GCC visibility must be followed by push or pop"); else { if (pop == action) { if (!VEC_length (visibility, visstack)) GCC_BAD ("no matching push for %<#pragma GCC visibility pop%>"); else pop_visibility (); } else { if (pragma_lex (&x) != CPP_OPEN_PAREN) GCC_BAD ("missing %<(%> after %<#pragma GCC visibility push%> - ignored"); token = pragma_lex (&x); if (token != CPP_NAME) GCC_BAD ("malformed #pragma GCC visibility push"); else push_visibility (IDENTIFIER_POINTER (x)); if (pragma_lex (&x) != CPP_CLOSE_PAREN) GCC_BAD ("missing %<(%> after %<#pragma GCC visibility push%> - ignored"); } } if (pragma_lex (&x) != CPP_EOF) warning (OPT_Wpragmas, "junk at end of %<#pragma GCC visibility%>"); } #endif static void handle_pragma_diagnostic(cpp_reader *ARG_UNUSED(dummy)) { const char *kind_string, *option_string; unsigned int option_index; enum cpp_ttype token; diagnostic_t kind; tree x; if (cfun) { error ("#pragma GCC diagnostic not allowed inside functions"); return; } token = pragma_lex (&x); if (token != CPP_NAME) GCC_BAD ("missing [error|warning|ignored] after %<#pragma GCC diagnostic%>"); kind_string = IDENTIFIER_POINTER (x); if (strcmp (kind_string, "error") == 0) kind = DK_ERROR; else if (strcmp (kind_string, "warning") == 0) kind = DK_WARNING; else if (strcmp (kind_string, "ignored") == 0) kind = DK_IGNORED; else GCC_BAD ("expected [error|warning|ignored] after %<#pragma GCC diagnostic%>"); token = pragma_lex (&x); if (token != CPP_STRING) GCC_BAD ("missing option after %<#pragma GCC diagnostic%> kind"); option_string = TREE_STRING_POINTER (x); for (option_index = 0; option_index < cl_options_count; option_index++) if (strcmp (cl_options[option_index].opt_text, option_string) == 0) { /* This overrides -Werror, for example. */ diagnostic_classify_diagnostic (global_dc, option_index, kind); /* This makes sure the option is enabled, like -Wfoo would do. */ if (cl_options[option_index].var_type == CLVC_BOOLEAN && cl_options[option_index].flag_var && kind != DK_IGNORED) *(int *) cl_options[option_index].flag_var = 1; return; } GCC_BAD ("unknown option after %<#pragma GCC diagnostic%> kind"); } /* Stack of the #pragma GCC options created with #pragma GCC option push. */ static GTY(()) VEC(tree,gc) *option_stack; /* Parse #pragma GCC option (xxx) to set target specific options. */ static void handle_pragma_option(cpp_reader *ARG_UNUSED(dummy)) { enum cpp_ttype token; const char *name; tree x; bool close_paren_needed_p = false; if (cfun) { error ("#pragma GCC option is not allowed inside functions"); return; } if (!targetm.target_option.pragma_parse) { error ("#pragma GCC option is not supported for this system"); return; } token = pragma_lex (&x); if (token == CPP_OPEN_PAREN) { close_paren_needed_p = true; token = pragma_lex (&x); } if (token == CPP_NAME) { bool call_pragma_parse_p = false; bool ok_p; name = IDENTIFIER_POINTER (x); if (strcmp (name, "reset") == 0) { current_option_pragma = NULL_TREE; call_pragma_parse_p = true; } else if (strcmp (name, "push") == 0) VEC_safe_push (tree, gc, option_stack, copy_list (current_option_pragma)); else if (strcmp (name, "pop") == 0) { int len = VEC_length (tree, option_stack); if (len == 0) { GCC_BAD ("%<#pragma GCC option pop%> without a %<#pragma GCC " "option push%>"); return; } else { VEC_truncate (tree, option_stack, len-1); current_option_pragma = ((len > 1) ? VEC_last (tree, option_stack) : NULL_TREE); call_pragma_parse_p = true; } } else { GCC_BAD ("%<#pragma GCC option%> is not a string or " "push/pop/reset"); return; } token = pragma_lex (&x); if (close_paren_needed_p) { if (token == CPP_CLOSE_PAREN) token = pragma_lex (&x); else GCC_BAD ("%<#pragma GCC option ([push|pop|reset])%> does not " "have a final %<)%>."); } if (token != CPP_EOF) { GCC_BAD ("%<#pragma GCC option [push|pop|reset]%> is badly " "formed"); return; } /* See if we need to call the pragma_parse hook. This must occur at the end after processing all of the tokens, or we may get spurious errors when we define or undef macros. */ ok_p = targetm.target_option.pragma_parse (current_option_pragma); gcc_assert (ok_p); } else if (token != CPP_STRING) { GCC_BAD ("%<#pragma GCC option%> is not a string or push/pop/reset"); return; } /* Strings are user options. */ else { tree args = NULL_TREE; do { /* Build up the strings now as a tree linked list. Skip empty strings. */ if (TREE_STRING_LENGTH (x) > 0) args = tree_cons (NULL_TREE, x, args); token = pragma_lex (&x); while (token == CPP_COMMA) token = pragma_lex (&x); } while (token == CPP_STRING); if (close_paren_needed_p) { if (token == CPP_CLOSE_PAREN) token = pragma_lex (&x); else GCC_BAD ("%<#pragma GCC option (string [,string]...)%> does " "not have a final %<)%>."); } if (token != CPP_EOF) { error ("#pragma GCC option string... is badly formed"); return; } /* put arguments in the order the user typed them. */ args = nreverse (args); if (targetm.target_option.pragma_parse (args)) current_option_pragma = args; } } /* Stack of the #pragma GCC optimize options created with #pragma GCC optimize push. */ static GTY(()) VEC(tree,gc) *optimize_stack; /* Handle #pragma GCC optimize to set optimization options. */ static void handle_pragma_optimize(cpp_reader *ARG_UNUSED(dummy)) { enum cpp_ttype token; const char *name; tree x; bool close_paren_needed_p = false; tree optimization_previous_node = optimization_current_node; if (cfun) { error ("#pragma GCC optimize is not allowed inside functions"); return; } token = pragma_lex (&x); if (token == CPP_OPEN_PAREN) { close_paren_needed_p = true; token = pragma_lex (&x); } if (token == CPP_NAME) { bool call_opt_p = false; name = IDENTIFIER_POINTER (x); if (strcmp (name, "reset") == 0) { struct cl_optimization *def = TREE_OPTIMIZATION (optimization_default_node); current_optimize_pragma = NULL_TREE; optimization_current_node = optimization_default_node; cl_optimization_restore (def); call_opt_p = true; } else if (strcmp (name, "push") == 0) VEC_safe_push (tree, gc, optimize_stack, current_optimize_pragma); else if (strcmp (name, "pop") == 0) { int len = VEC_length (tree, optimize_stack); if (len == 0) { GCC_BAD ("%<#pragma GCC optimize pop%> without a %<#pragma " "GCC optimize push%>"); return; } else { VEC_truncate (tree, optimize_stack, len-1); current_optimize_pragma = ((len > 1) ? VEC_last (tree, optimize_stack) : NULL_TREE); call_opt_p = true; if (current_optimize_pragma) { bool ok_p = parse_optimize_options (current_optimize_pragma, false); gcc_assert (ok_p); /* should be parsed previously. */ optimization_current_node = build_optimization_node (); } else { struct cl_optimization *opt = TREE_OPTIMIZATION (optimization_default_node); optimization_current_node = optimization_default_node; cl_optimization_restore (opt); } } } else { GCC_BAD ("%<#pragma GCC optimize%> is not a string or " "push/pop/reset"); return; } token = pragma_lex (&x); if (close_paren_needed_p) { if (token == CPP_CLOSE_PAREN) token = pragma_lex (&x); else GCC_BAD ("%<#pragma GCC optimize ([push|pop|reset])%> does not " "have a final %<)%>."); } if (token != CPP_EOF) { GCC_BAD ("%<#pragma GCC optimize [push|pop|reset]%> is badly " "formed"); return; } if (call_opt_p && (optimization_previous_node != optimization_current_node)) c_cpp_builtins_optimize_pragma (parse_in, optimization_previous_node, optimization_current_node); } else if (token != CPP_STRING && token != CPP_NUMBER) { GCC_BAD ("%<#pragma GCC optimize%> is not a string, number, or " "push/pop/reset"); return; } /* Strings/numbers are user options. */ else { tree args = NULL_TREE; do { /* Build up the numbers/strings now as a list. */ if (token != CPP_STRING || TREE_STRING_LENGTH (x) > 0) args = tree_cons (NULL_TREE, x, args); token = pragma_lex (&x); while (token == CPP_COMMA) token = pragma_lex (&x); } while (token == CPP_STRING || token == CPP_NUMBER); if (close_paren_needed_p) { if (token == CPP_CLOSE_PAREN) token = pragma_lex (&x); else GCC_BAD ("%<#pragma GCC optimize (string [,string]...)%> does " "not have a final %<)%>."); } if (token != CPP_EOF) { error ("#pragma GCC optimize string... is badly formed"); return; } /* put arguments in the order the user typed them. */ args = nreverse (args); parse_optimize_options (args, false); optimization_current_node = build_optimization_node (); c_cpp_builtins_optimize_pragma (parse_in, optimization_previous_node, optimization_current_node); } } /* Print a plain user-specified message. */ static void handle_pragma_message (cpp_reader *ARG_UNUSED(dummy)) { enum cpp_ttype token; tree x, message = 0; token = pragma_lex (&x); if (token == CPP_OPEN_PAREN) { token = pragma_lex (&x); if (token == CPP_STRING) message = x; else GCC_BAD ("expected a string after %<#pragma message%>"); if (pragma_lex (&x) != CPP_CLOSE_PAREN) GCC_BAD ("malformed %<#pragma message%>, ignored"); } else if (token == CPP_STRING) message = x; else GCC_BAD ("expected a string after %<#pragma message%>"); gcc_assert (message); if (pragma_lex (&x) != CPP_EOF) warning (OPT_Wpragmas, "junk at end of %<#pragma message%>"); if (TREE_STRING_LENGTH (message) > 1) inform (input_location, "#pragma message: %s", TREE_STRING_POINTER (message)); } /* A vector of registered pragma callbacks. */ DEF_VEC_O (pragma_handler); DEF_VEC_ALLOC_O (pragma_handler, heap); static VEC(pragma_handler, heap) *registered_pragmas; typedef struct { const char *space; const char *name; } pragma_ns_name; DEF_VEC_O (pragma_ns_name); DEF_VEC_ALLOC_O (pragma_ns_name, heap); static VEC(pragma_ns_name, heap) *registered_pp_pragmas; struct omp_pragma_def { const char *name; unsigned int id; }; static const struct omp_pragma_def omp_pragmas[] = { { "atomic", PRAGMA_OMP_ATOMIC }, { "barrier", PRAGMA_OMP_BARRIER }, { "critical", PRAGMA_OMP_CRITICAL }, { "flush", PRAGMA_OMP_FLUSH }, { "for", PRAGMA_OMP_FOR }, { "master", PRAGMA_OMP_MASTER }, { "ordered", PRAGMA_OMP_ORDERED }, { "parallel", PRAGMA_OMP_PARALLEL }, { "section", PRAGMA_OMP_SECTION }, { "sections", PRAGMA_OMP_SECTIONS }, { "single", PRAGMA_OMP_SINGLE }, { "task", PRAGMA_OMP_TASK }, { "taskwait", PRAGMA_OMP_TASKWAIT }, { "threadprivate", PRAGMA_OMP_THREADPRIVATE } }; void c_pp_lookup_pragma (unsigned int id, const char **space, const char **name) { const int n_omp_pragmas = sizeof (omp_pragmas) / sizeof (*omp_pragmas); int i; for (i = 0; i < n_omp_pragmas; ++i) if (omp_pragmas[i].id == id) { *space = "omp"; *name = omp_pragmas[i].name; return; } if (id >= PRAGMA_FIRST_EXTERNAL && (id < PRAGMA_FIRST_EXTERNAL + VEC_length (pragma_ns_name, registered_pp_pragmas))) { *space = VEC_index (pragma_ns_name, registered_pp_pragmas, id - PRAGMA_FIRST_EXTERNAL)->space; *name = VEC_index (pragma_ns_name, registered_pp_pragmas, id - PRAGMA_FIRST_EXTERNAL)->name; return; } gcc_unreachable (); } /* Front-end wrappers for pragma registration to avoid dragging cpplib.h in almost everywhere. */ static void c_register_pragma_1 (const char *space, const char *name, pragma_handler handler, bool allow_expansion) { unsigned id; if (flag_preprocess_only) { pragma_ns_name ns_name; if (!allow_expansion) return; ns_name.space = space; ns_name.name = name; VEC_safe_push (pragma_ns_name, heap, registered_pp_pragmas, &ns_name); id = VEC_length (pragma_ns_name, registered_pp_pragmas); id += PRAGMA_FIRST_EXTERNAL - 1; } else { VEC_safe_push (pragma_handler, heap, registered_pragmas, &handler); id = VEC_length (pragma_handler, registered_pragmas); id += PRAGMA_FIRST_EXTERNAL - 1; /* The C++ front end allocates 6 bits in cp_token; the C front end allocates 7 bits in c_token. At present this is sufficient. */ gcc_assert (id < 64); } cpp_register_deferred_pragma (parse_in, space, name, id, allow_expansion, false); } void c_register_pragma (const char *space, const char *name, pragma_handler handler) { c_register_pragma_1 (space, name, handler, false); } void c_register_pragma_with_expansion (const char *space, const char *name, pragma_handler handler) { c_register_pragma_1 (space, name, handler, true); } void c_invoke_pragma_handler (unsigned int id) { pragma_handler handler; id -= PRAGMA_FIRST_EXTERNAL; handler = *VEC_index (pragma_handler, registered_pragmas, id); handler (parse_in); } /* Set up front-end pragmas. */ void init_pragma (void) { if (flag_openmp) { const int n_omp_pragmas = sizeof (omp_pragmas) / sizeof (*omp_pragmas); int i; for (i = 0; i < n_omp_pragmas; ++i) cpp_register_deferred_pragma (parse_in, "omp", omp_pragmas[i].name, omp_pragmas[i].id, true, true); } if (!flag_preprocess_only) cpp_register_deferred_pragma (parse_in, "GCC", "pch_preprocess", PRAGMA_GCC_PCH_PREPROCESS, false, false); #ifdef HANDLE_PRAGMA_PACK #ifdef HANDLE_PRAGMA_PACK_WITH_EXPANSION c_register_pragma_with_expansion (0, "pack", handle_pragma_pack); #else c_register_pragma (0, "pack", handle_pragma_pack); #endif #endif #ifdef HANDLE_PRAGMA_PUSH_POP_MACRO c_register_pragma (0 ,"push_macro", handle_pragma_push_macro); c_register_pragma (0 ,"pop_macro", handle_pragma_pop_macro); #endif #ifdef HANDLE_PRAGMA_WEAK c_register_pragma (0, "weak", handle_pragma_weak); #endif #ifdef HANDLE_PRAGMA_VISIBILITY c_register_pragma ("GCC", "visibility", handle_pragma_visibility); #endif c_register_pragma ("GCC", "diagnostic", handle_pragma_diagnostic); c_register_pragma ("GCC", "option", handle_pragma_option); c_register_pragma ("GCC", "optimize", handle_pragma_optimize); c_register_pragma_with_expansion (0, "redefine_extname", handle_pragma_redefine_extname); c_register_pragma (0, "extern_prefix", handle_pragma_extern_prefix); c_register_pragma_with_expansion (0, "message", handle_pragma_message); #ifdef REGISTER_TARGET_PRAGMAS REGISTER_TARGET_PRAGMAS (); #endif } #include "gt-c-pragma.h"